Transfer mechanism for calculating



Oct. 21, 1947. T. o. MEHAN ETAL TRANSFER MECHANISM FOR CALCULATING MACHINES Original Filed March 6, 1942 6 Sheets-Sheet l S M m m m 2W 0. Malian BY Hunzfier E. Hoae Oct; 21, 1947. J

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TRANSFER MECHANISM FORCALCULATING MACHINES e Sheets-Sheet 2 Original Filed March 6, 19 42- INVENTORS Y Thomas O. Me/uxn Hunter E. Home BY Lm ,MX- ,1 M fii'omeysz Oct. 21, 1947. T. o. MEHAN ETAL 2 TRANSFER MECHANISM FOR CALCULATING MACHINES Original-Filed March 6,1942 6 SheetS -Sheet 3 I NVENTORS T llamas W0. llefzan BY Hun-21a? E. Home Oct. 21, A 'r. o. MEHAN Firm.

TRANSFER MECHANISM FOR CALCULATING MACHINES Original Filed March 6, 1942 6 Sheets-Sheet 4 Hunter E fiiorne ys Oct. 21, '1947.

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Patented Oct. 21 1947 TRANSFER MECHANISM FOR CALCULATING MACHINES Thomas O. Mehan, Park Ridge, and Hunter E. Hooe, Chicago, 111., assignors to Victor Adding Machine (30., Chicago, Ill., a corporation of Illinois Original application March 6, 1942, Serial No. 433,608, new Patent No. 2,396,188, dated March 5,1946. Divided and this application May 30, 1945, Serial No. 596,762

'7 Claims.

Our invention relates generally to calculating machines, and more particularly to improvements in subtracting, positive and negative total taking, and control mechanisms for machines of this type.

The invention is an improvement upon the machine disclosed in the prior patents of Thomas O. Mehan, Nos. 2,346,265 and 2,360,005, and is a division of our copending application Serial No. 433,608, filed March 6, 1942, which has matured into Patent No. 2,396,188.

It is a primary object of our invention to provide an improved calculating machine capable of addition and subtraction (as well as division and multiplication by repeated addition and sub" traction), in which positive or negative totals may be taken during the machine cycle immediately following an item entering cycle, that is, without the necessity of interposing one or more blank strokes.

A further object is to provide an improved carrying or transfer mechanism whereby transfers may be effected substantially instantaneously from the lowest-through intermediate-to the highest denominational order of the accumulator during the initial portion of a normal operating cycle.

A further object is to provide an improved calculating machine Which is capable of performing a wide variety of calculating operations efficiently and rapidly, which is simple in construction,

and which may be economically manufactured.

Other objects will appear from the following description, reference being had to the accompanying drawings, in which:

Fig. 1 is a vertical sectional view, taken from the left side of the machine, and showing the numeral keys, the accumulator, and the actuating mechanism therefor;

Fig. 2 is a fragmentary vertical sectional view, taken just inside the left outer vertical frame of the machine, and showing particularly the means for shifting the accumulator between add and subtract positions, and the means for operating the actuator restoring bail;

Fig. 3 is a fragmentary vertical sectional View, to an enlarged scale, showing the accumulator and its associated operating mechanism;

Fig. 3a is a fragmentary sectional View showing particularly the non-add latch.

Figs. 4 to 8 are fragmentary sectional views, showing portions of the transfer or carrying mechanism in the different positions assumed thereby in effecting transfers;

Fig. 9 is a right-side elevational view of a por tion of the machine with the casing removed,

2 V showing particularly the control keys and linkage operated thereby;

Fig. 10 is a perspective view showing the connection between the credit balance, total, and subtotal keys and the subtract and add keys;

Fig. 11 is a plan View of the accumulator mechanism, portions thereof being omitted to reveal the underlying parts; and

Fig, 12 is a timing chartshowing the sequence of operations taking place during listing and total taking cycles of the machine.

General description It is believed that the detailed description of the machine will be more readily understood if it is read with a general knowledge of the functions to be performed and the general manner in which the objects of the invention are attained.

The machine is of the key-set type, the keys controlling the positioning of actuators which operate the accumulators. Intermediate the actuator racks and the accumulators is a novel form of motion transmitting mechanism whereby transfer operations may be rapidly effected during a very short time near the beginning of an operating cycle. The accumulator pinions are shifted between add and subtract positions, depending upon which of the control keys is depressed, by electromagnetic means, which are operated substantially instantaneously upon depression of the control keys.

Means are provided automatically to add the fugitive one as the amount entered in the accumulator changes from a positive to anegative value, and to subtract the fugitive one from the amount in the accumulator as such amount changes from a negative to a positive value.

By virtue of the fact that the fugitive one is thus added or subtracted, and because the transfer or carry-over mechanism and the accumulator shift mechanism operate rapidly at the beginning of an operating cycle, it is possible to take a posi tive or negative total and clear the accumulators in the cycle of operation immediately following an item entering cycle. The necessity of taking one or more blank strokes or spacing cycles is thus avoided.

Accumulator, and actuating mechanism therefor As shown in Fig. 1, the machine has numeral keys 20 which may be provided with any suitable flexible latching mechanism for their key stems 22, and are suitably supported and guided for vertical reciprocatory movement, the keys be ing returned to normalposition by coil springs '24 extending through a transverse row of keys and supported intermediate the keys. The lower extremities of the key stems 22 serve as stops for cooperation with lugs 28 projecting sidewardly, alternately in opposite directions, from actuator slide 28. The stop lugs 28 are arranged in Vernier fashion so as to decrease the extent of necessary longitudinal movement of the slides Each of the slides has a bracket 38 secured there-- to, these brackets being suitably offset and each provided with a notch 32 engageable with a pin 34 projecting sidewardly from an actuating rack 36. Each of the slides 28 is normally restrained from rearwardly movement (under conditions hereinafter to be described) by a zero stop hook 37. The slides in such of the denominational orders in which a key has been depressed are released by clockwise swinging of their respective zero stop hooks 3'! in a conventional manner.

The actuating racks 36 are mounted for longitudinal reciprocatory movement upon a pair of fixed guide rods 38 extending through slots 39, and are laterally spaced by suitable conventional means, such as combs 4!. The actuating racks 38 are normally urged to move rearwardly by tension springs 48 in the usual manner. Extending through slots 42 formed in the actuating racks 38 is a restoring bail bar 44, which is suitably guided in the center frame plates of the machine.

for reciprocation in the direction of the slots 42, such as by the slot 48 formed in the left-hand one of a pair of center frame plates 48, 49. A link 38 (Fig. 2) is suitably secured at each end of the restoring bar 44. The rearward ends of the links 58 are pivotally connected to arms 52, which are rigidly secured to a shaft 54, mounted for oscillation in the center vertical frame plates. The arm 52 at the left-hand end of the shaft 54 is formed integrally with an offset arm 58, which carries a follower roller 58, the latter being held in engagement with a plate cam 68 by a spring BI. The cam 89 is secured to a main shaft 82.

As will hereinafter appear, the main shaft 82 rotates counterclockwise (Fig. 2) through a complete revolution during each operating cycle of the machine. As may be observed from Fig. 2, and as indicated in the diagram of Fig. 12, the cam 88 has a depressed portion 64 followed by a slight rise 85, a dwell portion 88, a sharp fall portion 88, a dwell portion 89, a rise portion I8, and a final dwell portion II. As a result of this shape of the plate cam 68, the restoring bar 44 moves in the following manner, as indicated in the chart of Fig. 12.

During the first 36 degrees of rotation of the main shaft, the restoring bar permits the actuating racks to be moved rearwardly (to the left, Fig. 1) from their normal position by their springs 48, which resets any tripped transfer pawls, as will appear hereinafter. As the depressed portion 84 of the cam passes the roller, the actuator racks 38 are moved forwardly, while the main shaft rotates from its 36 position to its 60 position. While the main shaft moves from its 60 position to its 75 position, the dwell portion 68 of the cam is adjacent the roller 58 and the actuating racks 38 are thus held stationary during this period.

From the 75 position to the 188 position, the sharp fall portion 88 of the cam passes the roller 58, so that the actuator racks 36 move rearwardly to the position in which they are limited by the stems of any depressed keys.

The rise portion I8 of the cam 68 commences 4 engaging the roller 58 to move the restoring bar 44 forwardly when the main shaft is at its 243 position, such forward motion being completed when the main shaft reaches its 288 position.

As shown in Figs. 1 to 6, each of the actuator racks 38 has a rack portion 82 meshing with a segmental pinion 84. This pinion is mounted for rotation upon a shaft 88, and is keyed to a segmental gear 88 by a lug 98 partially punched from the segmental gear 88. An aligner bar 85 (Fig. 2) is provided to align the segmental gears 88 prior to effecting the printing. The bar 85 may be operated in a conventional manner as shown, for example in the aforesaid Patent No. 2,346,265.

Each of the segmental gears has cut away portions 92 to receive a transfer sector 94 having three teeth in alignment with the teeth of the segmental gear 88. The transfer sector 94 is secured to a hub 95, which is mounted for rotation on the shaft 86. The transfer sector 94 is normally urged clockwise (Fig. 4), with respect to its adjacent gear segment 88, by a tension spring 98, one end of which is suitably anchored to the gear segment 88 and the other end of which is attached to an ear 98, extending from the transfer sector 94. The transfer sector 94 is normally held a definite arcuate distance, (corresponding to the tooth pitch) from the segmental gear 88 by the stop face 99 of a transfer pawl I88. When the transfer pawl is tripped, as will hereinafter be described, the stop face 99 moves radially inwardly with respect to a stop lug I82 formed on the transfer sector 94 and permits the latter to move clockwise under the influence of its spring 96 and enter a notch I84 formed in the transfer pawl I88 (Fig. 5).

The accumulator comprises a plurality of accumulator wheels I86 (pinions) mounted for free rotation upon a shaft I88, these pinions being at all times in mesh with subtract pinions III] mounted upon a haft H2, and the latter, as shown in Fig. 3, meshing with idler pinions II4 mounted upon a shaft I I 5, the idler pinions meshing with pinions I I8 attached to visible dial wheels I28 mounted for free rotation upon a shaft I22. The shafts I88, H2, H5, and I22 are rigidly secured to a pair of accumulator frame plates I24 and I25.

The ends of the shafts I88 and II 2 are provided with bushings I28 located in slots I28 formed in the cradle side plates I39 and I3I. The cradle side plates I38 and I3I are secured to gether to form a rigid cradle by rods I32, I33, and I 34, the rod I33 extending beyond the outer surfaces of the cradle frame plates I38 and I3I, and into suitable openings formed in the center section frame plates 48, 49, to provide a pivot for the cradle.

The cradle for the accumulators is rocked to bring the accumulator wheels I86 into mesh with the segmental gears 88 (or to bring the subtract pinions into meshing engagement, provided a substract operation is to be performed) by suitable mechanism, best shown in Fig. 3.

This mechanism comprises a link I35 pivoted on the rod I34. A lost motion pin and slot connection is provided between the lower end of the link I36 and the rearwardly extending arm I38 of a two armed lever I48, the forwardly projecting arm of which is pivotally connected to the upper end of an operating link I42. The link I42 is raised and lowered at the proper times in the operating cycle, depending upon the character of the operation performed, by suitable mechanism, such as is more fully disclosed in the aforesaid Patent No. 2,360,005.

A non-add latch I44, pivoted on the rod I34, when in the position shown in Fig. 3, prevents lost motion between the link I36 and the arm I38. This non-add latch I44 is swung rearwardly free from engagement with the pin on the arm I30 when a non-add 0 eration is to be performed, so that the raising and lowering of the operating link 5422 will be ineffective to swing the cradle.

The swinging movement of the accumulator carrying cradle is limited by a pin I48 projecting inwardly from the right center frame plate 49 and embraced in an elongated slot I48 formed in an ear I50, depending from and forming part of the cradle side plate I30. The ear I50 also has a nose portion I52 cooperable with a detent I54 pivoted on the shaft 86 and operated by a tension spring I56.

The transfer pawls I00 are pivoted on a shaft I58 carried in the center frame plates 48 and 40 and each is urged to swing clockwise (Fig. 3) by a tension spring I00 attached to the forwardly extending portion of the transfer pawl I00 and a rearwardly extending arm I62 of a transfer pawl latch i554. The latch I04 is notched at its upper end to receive the downwardly extending hook 366 at the forward end of the transfer pawl I00. of the accumulator pinions I00 is provided with a transfer cam tooth I68, and each of the subtract pinions IIO is similarly provided wi h a transfer cam tooth I (Fig. 4). The transfer cam teeth I68, I10 (depending upon whether an adding or subtracting operation is being performed) are adapted to contact a nose projection I12 formed on the transfer pawl I00 when a transfer is to be effected.

Such engagement causes the transfer pawl I00 to be swung counterclockwise (Fig. 3), whereupon the latch Ifi-t associated therewith is released from the hook I66 and swings clockwise so as to hold the transfer pawl I00 in tripped position, such holding being effected by the positioning of end portion I14 of the latch I64 beneath the hook 506.

The latches Hi l are restored incidental to the disengagement of the accumulator or subtract pinions from the actuators when the side plates I30, I3I of the cradle swing clockwise (Fig. 3). Under these circumstances, the rod I32 which joins these plates I30, I3I, engages such of the latches I64 as have been tripped and swings them counterclockwise sufficiently to permit the transfer pawls I00 to be returned by their springs I00 to their normal positions and to permit the hook portions I66 thereon to hold the latches I64 in restored position.

Suitable detent plates I13 and I15 are provided for the accumulator pinions I06 and subtract pinions I 10, respectively, to hold the pinions against rotation when they are not in engagement with the segmental gears 88. These detent plates may be operated by any suitable conventional means driven from the main operating shaft.

In order to insert the fugitive one and to subtract it at the proper times when the amount entered in the accumulator pinions changes from a positive to a negative value, and vice versa, the transfer pawls l00a and M01), respectively, for the highest and the lowest denominational order accumulator pinions I06, have rearwardly extending portions I16 connected by a bar I18. This fugitive one inserting mechanism is not claimed herein and may be of any suitable wellknown construction.

Accumulator shifting mechanism As previously indicated, the frame comprising the accumulator frame plates I24, I25 is shiftable in the cradle frame plates I30, I3ll, to bring either the accumulator pinions I06 or the subtract pine ions IIO in position for engagement with the segmental gears 88. Such shifting of these pinions is accomplished electromagnetically by a pair or solenoids I80, I82, having plungers I8I and I83, respectively. As best shown in Fig. 2, the plungers I8I and I83 are pivotally connected to the ends of the lever I84 centrally pinned to the shaft 86. Likewise secured to the shaft 86 is a pair of forked arms I86, the forked upper ends of which embrace sidewardly extending studs I88, which are secured to the accumulator frame plates I24, I25, respectively.

Thus, when the solenoid I is energized, the accumulator pinions I06 are brought to the position shown in Fig. 4, Where they may be brought into mesh with the transfer sectors 94 and gear segments 83. When in this position, the transfer cam teeth I68 are in positions such that they may operate the transfer pawls I00 and WM. On the other hand, when the solenoid I32 is energized, the accumulator assembly will be moved to the position shown in Fig. 1, wherein the subtract pinions IIO are in position for engagement with the transfer sectors 94 and gear segments 08, and the transfer cam teeth I10, associated with these pinions, may cooperate with the transfer pawls I00 and I000. for effecting transfer operations.

The accumulator assembly is held in the particular position to which it is shifted upon opera-, tion of either of the solenoids I80, I82, by any suitable detent.

Control keys and operating controls Referring to Fig. 9, it will be seen that the machine is provided with a plurality of control keys, including a non-print control key 200, a non-add key 20I, a subtotal key 202, a total key 203, a credit balance key 204, a repeat key 205, an error key 206, an add key 201, and a subtract key 208. The keys 200 to 206 operate in a manner more fully disclosed in the aforesaid Patents Nos. 2,346,265 and 2,360,005, to determine the character of the operating cycle to be performed. In addition, the keys 20I to 204, inclusive, are individually operable to close a switch 200, which, as is more completely disclosed in our Patent No. 2,396,188, results in the energization of the driving motor for initiation of a cycle of operation of the machine.

The add key 201 has an offset stem 2I2, which, at its lower end, is provided with a foot 2 I4. Similarly, the subtract key 208 has an offset stem 2I6 provided with a foot 2I8. The key stems 2I2 and 2I6 are provided with longitudinal slots embracing guiding studs 220 and 22 I. An interlock finger r 222 is freely pivoted on the stud 220 and has cam faces for engagement with studs 223 and 224 projecting sidewardly from the key stems 2I2 and 2I6, respectively, and prevents simultaneous depression of the keys 201 and 208.

The key 201 is adapted to be held in depressed position by a latch 226, while a similar latch 22-1 is provided for the subtract key 208. These latches, upon complete depression of the key 201 or key 208, are adapted to hook beneath the studs 220 or 229, respectively, to hold down the depressed key during a predetermined portion of the operating cycle. The latches 226 and 221 are adapted to be released by a reciprocatory slide 235 operated by suitable mechanism driven from the main shaft 82.

As shown in Fig. 10, the credit balance key 204 is adapted, upon depression, to swing clockwise a rocker plate 232 suitably supported in the keyboard assembly, the rocker plate 232 having a rearwardly extending arm 234 which overlies a pin 238 projecting inwardly from the key stem 2H3. In a similar manner, the subtotal key 202 and total key 288 are each provided with rocker plates having arms engageable with studs 238 and respectively, which are secured to the adding key stem 2I2.

Depression of the add key 201 causes its foot 2H5 to close a switch 240 and thereafter to close a switch 282. In a similar manner, complete depression of the subtract key 288 causes the foot 2I8 of its key stem successively to close switches 24 and 2 38.

Closure of switch 248, as shown in our Patent No. 2,396,188, results in energization of solenoid I 88, while closure of switch 244 energizes solenoid 82, to shift the accumulator provided it is not already in the correct position for the character of the operation to be performed. Closure of either switch 2 :2 or 248 results in the initiation of an operating cycle of the machine.

Operation The machine is operated in a normal manner in setting up the amount by depression of appropriate amount keys 28. While the keyboard is indicated as of the full flexible type, it will be readily understood that this is not essential and that a ten-key amount-setup mechanism may be employed.

After setting up the amount, the operator depresses either the add key 201 or the subtract key 288, depending upon the character of the operation to be performed. If for example, the preceding operation has been a subtract operation and the operator depressed the add key 281, the initial portion of the downward stroke of the add key 28'. results in closure of the switch 240. As previously described, closure of the switch 240 would, in this instance, result in the energization of the solenoid I88. The accumulator pinions I88 are thus in the positions shown in Figs. 4, 5, 7, and 8.

Further depression of the add key 281 results in the closure of drive motor control switch 242.

The motor will thus commence driving the main shaft 82 through the usual one revolution clutch mechanism and, by means of the cam 60 (Fig. 2) move the restoring bail bar 44 rearwardly a short distance sufficient to move the segmental gears 88 from the positions in which they are shown in Fig. 4 to the positions shown in Fig. 6. In this position, the gear segment 88 is in contact with the transfer sector 84, and holds the latter sufiiciently counterclockwise from its normal position to permit any of the transfer pawls I88 which may have been moved to transfer position in a preceding cycle (as in Fig. 5), to swing from the dotted line position of Fig. 6 to the full line position. Such restoratiton of any previously actuated transfer pawls I08, I 80a, is permitted, since at this time the accumulator cradle frame plates I38 and [SI are in the position shown in Fig. 3, in which, it will be noted, the transfer pawl latches I84 are swung sufficiently counterclockwise to permit the springs I60 to move their respective transfer pawls I00, Illfla, to normal position.

Following restoration of the transfer pawls I00, I 00a, and after the main shaft has rotated through 36", the actuator restoring bail bar 44 will, as previously described, commence moving forward until at the 60 position of the main shaft, the gear segments 88 and transfer sectors 94 will be in their normal positions shown in Fig. 4. After being held in this position from a 60 to a 75 position of the main shaft, such of the racks as have been released by their zero stops 3! (due to the depression of a key in the associated bank of keys) will move rearwardly with the restoring bail bar 44 until arrested by the depressed key stems. As indicated in Fig. 12, all of the racks will have moved rearwardly to the limit permitted by their associated set keys when the main shaft has rotated through 108. When in this position, the segmental gears 88 are locked in aligned position by the aligner bar 85, and, after the main shaft has moved to its 207 position, the accumulator pinions I08 are rocked into engagement with the gear segments 88.

As the main shaft reaches its 231 position, the accumulators will be fully enmeshed with the gear segments 88 so that at the 234 position of the main shaft, the aligner bar may be, and is, moved from engagement with the segmental gears 88. t the 243 position of the main shaft, the aligner bar will be fully disengaged and the restoring bail bar M will commence moving forward, and reaches its normal forward position when the main shaft is at its 288 position. During the course of such movement, the actuating racks 38 which have been displaced due to the operation of a numeral key in their associated key banks will be successively picked up by the restorin bail 44 and returned to normal position, where they will be relatched by their zero stop hooks 31.

If, in the course of the forward movement of the actuator racks 38, one of the accumulator pinions I86 is rotated from its 9 to its 0 position,

its transfer cam tooth I58 trips the transfer pawl I88 or Ifit'a associated with the next highest denominational order so that the latter moves from the full line to the dotted line position of Fig. 6. The transfer sector 96 of the order into which the transfer is effected is thus permitted to be restored with its segmental gear 88 to the position in which it is shown in Fig. 5, and the accumulator pinion I88 in mesh therewith will thus be advanced an additional tooth space since the transfer sector 94 forms in effect a continuation of the gear segment 88.

After the main shaft reaches its 348 position, the accumulator pinions I86 are moved away from the segmental gears 88 and transfer sectors 94 so that as the cycle of operation is completed the accumulator pinions will again be in the positions in which they are shown in Figs. 4 and 5 and will have had the amount set up on the keyboard added to the registration which may have initially been contained therein.

It will be noted that in an ordinary listing operation (as well as other types of operating cycles to be described hereinafter), the transfer pawls I88, Inca are reset during the initial 60 movement of the main shaft so that transfer operations may be rapidly performed during the limited time that the accumulators are in engagement with their actuating gears 88 and transfer sectors 94. Furthermore, it will be noted that the movement of the transfer sectors 9 94 is effected by the springs 96, and that because of the relatively light weight and low rotary moment of inertia of the transfer sectors 94, these parts may move rapidly to the position in which they effect a transfer (1. e., from the position of Fig. 4 to that of Fig. 5). Thus, for example, if the accumulator contained the registration of the amount 999,999,999.99 prior to the start of the adding cycle, it will be apparent that if the amount added during the adding cycle was 1, all of the transfer pawls will have to be tripped. The energy for tripping the pawls I00, NM, and for rotating the accumulator pinions each through one step and effecting a transfer of the type indicated, is obtained from the stretched springs 96. Thus, the mechanism is capable of performing successive transfer operations from the units to the highest order accumulator pinion without requiring the movement of relatively heavy parts having considerable inertia, which would tend to slow down the transfer operation.

In performing a subtract operating cycle, the operator presses the keys representing the amount to be subtracted and follows this with the depression of the subtract key 208. The initial downward movement of the key 268 results in closure of the switch 244, which completes a circuit through the solenoid I82.

As the latter is energized, the accumulator assembly is shifted from the position in which it is shown in Figs. 4 and 6 to the position in which it is shown in Figs. 1 and 3, in which position the subtract pinions IIO are in position to be engaged with the segmental gears 88 and transfer sectors 94.

Further depression of the subtract key 268 results in closure of the switch 246, which completes the circuit to the one revolution clutch mechanism solenoid 260 in the same manner as was previously described as occurring upon the closure of switch 242.

The operating cycle of the machine commences, and all parts operate in the same manner as previously described with reference to the adding cycle, except that the subtract pinions H0, instead of the accumulator pinions I06, are brought into mesh with the gear segments 88 and transfer sectors 94, and the transfer pawls I00, I00b are actuated by the transfer cam teeth I'II) of the subtract pinions I I0 instead of by the corresponding transfer cam teeth of the accumulator pinions. Since the subtract pinions III) ar geared directly to the accumulator pinions I06, the amount set up on the keyboard will be subtracted from the registration contained in the accumulator pinions in the well known manner.

To illustrate a simple example involving a negative total, that is, a true total obtained when a greater amount is subtracted from a lesser amount, 4 subtracted from 3, for instance, the following operations occur: Assume that 3 has been entered into the units accumulator pinion I06, as illustrated in Fig. '7, with its transfer cam tooth I68 in the position there shown. Then as sume that digit 4 is set up in the keyboard, followed by a depression of the subtract key 206, to

perform a subtract operating cycle, in the manner previously described.

It will be recalled that the initial portion of the downward stroke given subtract ke 208 re- ,sults in shifting the subtract pinions I if! to proper position for meshing with the segmental gears 88 and transfer sectors 54 if, as in the present example, the prceding cycle was an adding operation. Thus, the units subtract pinion IIO Will be in position to mesh with the units segmental gear 88 (Fig. 3), and when so meshed, will be rotated four toothed spaces counterclockwise during the subtract cycle by virtue of the digit 4 set up in the keyboard. During such four toothed rotation of the unit subtract pinion H6, its associated transfer cam tooth I'Iil will trip its transfer pawl I00 when said pinion I00 moves between its 9 to 0 position to effect a transfer into the next highest denominational order subtract pinion. Such transfer operation accordingly takes place successively through the higher denominational order subtract pinions IIO until the tooth I10 of the highest denominational order pinion IIO trips its associated transfer pawl I00a (Fig, 11). When this pawl Iiifla is tripped, the transfer pawl Idilb is likewise tripped through a tie bar I18, and the units order subtract pinion H0 is thereby moved one additional toothed space to enter the fugitive one in the subtract pinion IIEi of lowest order. At this time, the registration in the subtract pinions III! will read 600,000,Gil0.01.

It may be convenient at this time to refer to the corresponding operation of the accumulator mechanism as the registration in the accumulator is changed from a negative value to a positive value. Such change would, of course, occur while the accumulator pinions I06 are in mesh with the actuating gear segments 88 or transfer sectors 94. With a registration of 999,999,999.99, all of the transfer cam teeth I68 of the accumulatorpinions I05 will be in position about to trip their associated transfer pawls I00, I00a. Thus, any further (counterclockwise, Fig. 4), movement of the units accumulator pinion I06 will trip the tens order transfer pawl I00 and advance the tens accumulator pinion I06 one tooth counterclockwise. This transfer will be carried through, in similar manner, to the highest order accumulator pinion I06, and from the latter to the units order accumulator pinion thus reinserting the fugitive one.

When a subtotal is to be taken, the subtotal key 262 is depressed. Depression of this key through its rocking plate 232 operating upon pin 238 depresses the key stem 2I2 of the add key 201, and, in the manner previously described sufficiently to close switch 240, thereby shifting the accumulator assembly to the add position (if it was not previously in that position) and subsequently by closure of switch 2I0 energizing the driving motor to start an operating cycle.

As the main shaft 62 reaches its 60 position, the accumulator pinions I06 are moved into mesh with the gear segments 88 and transfer sectors '94, and are retained in mesh throughout the rearward and forward travel of the actuating racks, being disengaged from the gear segments 88 and transfer sectors 94 as the main shaft reaches its 231 position.

In the subtotaling operation, the Zero hooks 31 are operated to release all of the actuating racks in the usual manner so that their movement may be limited by the engagment of the radial faces of the transfer cam teeth I68 with the cooperating surfaces of the noses I12 of the transfer pawls I90, Iota, all in a Well known manner, so that printing of the subtotal may be effected,

In efiecting a total operation, the total key 203 is operated, and an operating cycle corresponding closely with that described above with reference to taking a subtotal is performed by the machine, with the exception that the accumulator pinions I06 are disengaged from their gear segments 88 and. transfer sectors as the main shaft 62 moves 11 from its 207 to its 231 position so that the accumulator is cleared,

It will be understood that neither a total nor a subtotal operation can be performed b the machine while a credit balance or overdraft is present in the accumulator. Such operation may be prevented by any well known overdraft locking mechanism. When a credit balance is present in the accumulator and it is desired to print the credit balance and clear the machine, the credit balance key 284 is depressed. During the initial portion of the downward stroke of the key 204, it will, through the rocking plate 232, its arm 234, and pin 236, depress the subtract key stem 216 sufficiently to cause closure of the switch 244, thereby assuring that the accumulator assembly will be in its subtract position, energizing the solenoid I82 if necessary to thus shaft the accumulator assembly. Such shifting is necessary whenever the preceding cycle of the machine was an adding cycle.

Further depression of the credit balance key 204 results in closure of the switch 2 l and consequent initiation of an operating cycle. In the course of the credit balance operating cycle, just as in the subtotaling and totaling cycles, the zero hooks 31 are released during the operating cycle to permit the actuating racks 36 to move rearwardly to an extent determined by the positions of their associated subtract pinions H8, The rotation of the subtract pinions I H1 is limited by the engagement of the radial faces of their transfer cam teeth I with the cooperating faces of the noses I12 of the transfer pawls I00, 100a. When all of the subtract pinions have been arrested in this position, the accumulator pinions I08 are in positions corresponding to a registration of 999,999,999.99. This might be termed a negative zero position of the accumulator inions I06 since when in this position, if a unit is added in the units wheel, it will effect a successive transfer to the highest order wheels, first setting all of the wheels to zero position, and then, due to the rigid connection between the transfer pawls loud and I062), the unit will be entered into the units accumulator pinion by way of the transfer mechanism.

From the foregoing, it will be apparent that due to the rigid connection between the transfer pawls [00a and 1801), there is a possibility of erroneous addition by the amount of 1 for each time the capacity of the machine is exceeded in a single series of adding cycles, because after the full capacity of the machine, namely, 999,999,999.99, is reached, the addition of 1 will result in causing the accumulators to register 000,000,000.01, whereas, the indication should have been 000,000,000.00. However, this possibility of error is extremely remote and is of no more consequence than the possibility of error in the use of any adding or calculating machine whenever the capacity of the machine is exceeded.

Resume From the foregoing, it will appear that the machine of our invention is so constructed that a subtotal, a total, or a credit balance may be taken at any time, that is, during a cycle of the machine immediately following an add or subtract cycle. The factors which make this possible include the manner of resetting the transfer mechamsm, whereby this is accomplished during the first 60 of rotation of the main shaft, and the utilization of a means for shifting the accumulator between its add and subtract positions which is operable prior to the commencement of, or at least during the first few degrees of, the operating cycle.

The transfer mechanism, in which energy is stored and released to effect transfer operations with the movement of small low inertia parts, and the actuator operating means, whereby the resetting of the transfer mechanism is effected early in an operating cycle of the machine, contribute materially to the simplicity and speed of oDeration of the machine.

While we have shown and described a particular embodiment of our invention, it will be understood by those skilled in the art that the invention may be embodied in various modified forms, and we therefore desire, by the following claims, to include within the scope of our invention, all such variations and modifications by which substantially the results of our invention may be obtained through the use of substantially the same or equivalent means.

We claim:

1. In a calculating machine having actuators differentially positionable under the control of selectively set keys, an accumulator differentially operable by said actuators, a transfer mechanism associated with said accumulators, means operated by the actuators to restore the transfer mechanism to normal position and means to reciprocate said actuators through a relatively small excursion of sufiicient extent to restore the transfer mechanism to normal position prior to the time in the operating cycle that said actuators are reciprocated to effect a total taking, sub-total taking, adding, or subtracting operation of the machine.

2. In a calculating machine having an accumulator and a plurality of actuator racks for operating the accumulator, means for resiliently urging said racks in one direction, a restoring bail, and. means for operating said restoring bail during each complete cycle of operation of the machine to cause the latter to permit movement of said racks in two reciprocatory excursions with the first of said excursions of amplitude slightly more than necessary for the entry of unitary digits in said accumulator, and the second of said excursions of sufficient amplitude to permit movement of said actuators through their maximum strokes.

3. In a calculating machine having an accumulator provided with transfer device and a plurality of actuators for operating the accumulator, the combination of means individual to said actuators for yieldingly urging them in one direction from normal position, an element for moving said actuators in the opposite direction, and means for moving said element in two reciprocatory excursions during each operating cycle of the machine, the first of the excursions being a small amplitude suflicient to restore the transfer device and the second excursion of sumcient amplitude to permit movement of said actuators through their maximum strokes.

4. In a calculating machine having movable numeral stops, an accumulator, actuators for operating the accumulator in response to the setting of the stops, a quick acting transfer mechanism associated with the accumulator, said transfer mechanism including for each denominational order pawls which are tripped during adding or subtracting operations of the machine when a carry-over Or transfer is required, means operated by the initial movement of said actuators to reset any of said pawls which have been tripped during a preceding cycle, and means to impart to said actuators an initial oscillatory movement of sufficient extent to reset the tripped transfer pawls and thereafter impart to said actuators an oscillatory movement of extent necessary to effect actuation of the accumulator.

5. In a calculating machine having movable numeral stops, an accumulator, actuators for operating the accumulator in response to the setting of the stops, a transfer mechanism associated with the accumulator, said transfer mechanism including parts which are tripped during adding operations of the machine when a carryover or transfer is required, means operated by the initial movement of said actuators to reset any of said parts which have been tripped during a proceding cycle, and means to impart to said actuators an initial to and fro movement of sufficient extent to reset the tripped parts and thereafter to impart to said actuators a to and fro movement of extent necessary to effect actuation of the accumulator.

6. In a calculating machine having an accumulator, actuators for operating the accumulator, a transfer mechanism associated with the accumulator, said transfer mechanism including trippable pawls, means operated by initial movement of said actuators during each operating cycle of the machine to reset any of said pawls which have been tripped during a preceding cycle, and means to impart to said actuators an initial movement of suflicient extent to reset the tripped transfer pawls and thereafter impart to said actuators a movement of extent necessary to effect actuation of the accumulator.

'7. In a calculating machine having movable numeral stops, an accumulator, actuators for operating the accumulator in response to the setting of the stops, a quick acting transfer mechanism associated with the accumulator, said transfer mechanism including for each denominational order pawls which are tripped during adding or substracting operations of the machine when a carry-over or transfer is required, means operated by initial movement of said actuators to reset any of said pawls which have been tripped during a preceding cycle, and a cam to impart to said actuators an initial movement of sufficient extent to reset the tripped transfer pawls and thereafter impart to said actuators a movement of extent necessary to effect actuation of the accumulator.

THOMAS O. MEI-IAN. HUNTER E. HOOE.

REFERENCES CITED UNITED STATES PATENTS Name Date Barrett June 30, 1931 Number 

